English

KRW Composition Theorems via Lifting

Computational Complexity 2025-05-08 v3

Abstract

One of the major open problems in complexity theory is proving super-logarithmic lower bounds on the depth of circuits (i.e., P⊈NC1\mathbf{P}\not\subseteq\mathbf{NC}^1). Karchmer, Raz, and Wigderson (Computational Complexity 5(3/4), 1995) suggested to approach this problem by proving that depth complexity behaves "as expected" with respect to the composition of functions fgf\diamond g. They showed that the validity of this conjecture would imply that P⊈NC1\mathbf{P}\not\subseteq\mathbf{NC}^1. Several works have made progress toward resolving this conjecture by proving special cases. In particular, these works proved the KRW conjecture for every outer function ff, but only for few inner functions gg. Thus, it is an important challenge to prove the KRW conjecture for a wider range of inner functions. In this work, we extend significantly the range of inner functions that can be handled. First, we consider the monotone\textit{monotone} version of the KRW conjecture. We prove it for every monotone inner function gg whose depth complexity can be lower bounded via a query-to-communication lifting theorem. This allows us to handle several new and well-studied functions such as the s-ts\textbf{-}t-connectivity, clique, and generation functions. In order to carry this progress back to the non-monotone\textit{non-monotone} setting, we introduce a new notion of semi-monotone\textit{semi-monotone} composition, which combines the non-monotone complexity of the outer function ff with the monotone complexity of the inner function gg. In this setting, we prove the KRW conjecture for a similar selection of inner functions gg, but only for a specific choice of the outer function ff.

Cite

@article{arxiv.2007.02740,
  title  = {KRW Composition Theorems via Lifting},
  author = {Susanna F. de Rezende and Or Meir and Jakob Nordström and Toniann Pitassi and Robert Robere},
  journal= {arXiv preprint arXiv:2007.02740},
  year   = {2025}
}
R2 v1 2026-06-23T16:53:02.794Z